Posts Tagged ‘Topical’

Topical Bovine Thrombin Induces Vascular Cell Proliferation

Demet Sağ, Kamran Baig*, Steven Hanish*, Jeffrey Lawson




Running Foot:

Use of bovine thrombin induces the cell proliferation at anastomosis

Department of Surgery

Duke University Medical Center

Durham, NC 27710

United States of America

* Equally worked

Review Profs and correspondence should be addressed to:

Dr. Jeffrey Lawson

Duke University Medical Center

Room 481 MSRB/ Box 2622

Research Drive

Durham, NC 27710

Phone (919) 681-6432

Fax      (919) 681-1094


Topical Bovine Thrombin Induces Vascular Cell Proliferation


Specific Aim:  The main goal of this study is to determine how the addition of thrombin alters the proliferative response of vascular tissue leading to early anastomotic failure through G protein coupled receptor signaling.

Methods and Results:  Porcine external jugular veins were harvested at 24h and 1 week after exposed to 5,000 units of topical bovine thrombin during surgery.    Changes in mitogen activated protein kinases (MAPK), pERK, p-p38, pJNK, were analyzed by immunocytochemistry and immunoblotting.  Expression of PAR  (PAR1, PAR2, PAR3, PAR4) was evaluated using RT-PCR.  All thrombin treated vessels showed increased expression of MAPKs, and PAR receptors compared to control veins, which were not treated with topical thrombin.  These data suggest that proliferation of vascular tissues following thrombin exposure is at least in part due to elevated levels of pERK.  Elevated levels of p38 and pJNK may also be associated with an inflammatory on stress response of the tissue follow thrombin exposure.

Conclusion:  Bovine thrombin is a mitogen, which may significantly increase vascular smooth muscle cell proliferation following surgery and repair.  Therefore, we suggest that bovine thrombin use on vascular tissues seriously reconsidered.

Abbreviations: ERK, extracellular regulated kinase; ES, embryonic stem cells; JIP, JNK-interacting protein; JNK, c-Jun NH2-terminal kinase; JNKK, JNK kinase; JNKBP, JNK binding protein; MAPK, mitogen-activated protein kinase; MAPKK, MAPK kinase; MAPKKK, MAPKK kinase; MEK, MAPK/ERK kinase; MEKK, MEK kinase; MKK, MAPK kinase.

Keywords: Hemostatics, Signal transduction; Thrombin, PTGF


Topical thrombin preparations have been used as haemostatic agents during cardiovascular surgery for over 60 years [1-3] and may be applied as a spray, paste, or as a component of fibrin glue [4].  It is currently estimated that over 500,000 patients per year are exposed to topical bovine thrombin (TBT) or commercially known as JMI  during various surgical procedures.  Thrombin is used in an extensive array of procedures including, but not limited to, neuro, orthopedic, general, cardiac, thoracic, vascular, gynecologic, head and neck, and dental surgeries [5, 6].  Furthermore, its use in the treatment of pseudoaneurysms in vascular radiology [7, 8] and topical applications on bleeding cannulation sites of vascular access grafts in dialysis units is widespread [6].

Thrombin is part of a superfamily of serine protease enzymes that perform limited proteolysis on a number of plasma and cell bound proteins and has been extensively characterized regarding its proteolytic cleavage of fibrinogen to fibrin.  It is this process that underlies the therapeutic use of thrombin as a hemostatic agent. However, thrombin also leads to the activation of natural anticoagulant pathways via the activation of protein C when bound to thrombomodulin and also alters fibrinolytic pathways via its cleavage of thrombin- activateable fibrinolytic inhibitor (TAFI) [9].  Furthermore, thrombin is also a potent platelet activator, mitogen, chemoattractant, and vasoconstrictor [10].  Regulatory mechanisms controlling the proliferation, differentiation, or apoptosis of cells involve intracellular protein kinases that can transduce signals detected on the cell’s surface into changes in gene expression.

Through the activation of protease-activated receptors (PARs, a family of G-protein-coupled receptors), thrombin acts as a hormone, eliciting a variety of cellular responses [11, 12]. Protease activated receptor 1 (PAR1) is the prototype of this family and is activated when thrombin cleaves its amino-terminal extracellular domain. This cleavage produces a new N-terminus that serves as a tethered ligand which binds to the body of the receptor to effect transmembrane signaling. Synthetic peptides that mimic the tethered ligand of PAR activate the receptor independent of PAR1 cleavage. The diversity of PAR’s effects can be attributed to the ability of activated PAR1 to couple to G12/13, Gq or Gi [13]. Importantly, thrombin can elicit at least some cellular responses even after proteolytic inactivation, indicating possible action through receptors other than PARs.  Thrombin has been shown to affect a vast number of cell types, including platelets, endothelial cells, smooth muscle cells, cardiomyocytes, fibroblasts, mast cells, neurons, keratinocytes, monocytes, macrophages and a variety of lymphocytes, including B-cells and T-cells [12, 14-21].

Most prominent amongst the known signal transduction pathways that control these events are the mitogen-activated protein kinase (MAPK) cascades, whose components are evolutionarily highly conserved in structure and organization. Each consisting of a module of three cytoplasmic kinases: a mitogen-activated protein (MAP) kinase kinase kinase (MAPKKK), an MAP kinase kinase (MAPKK), and the MAP kinase (MAPK) itself.  There are three welldefined MAPK pathways: extracellular signal-protein regulated protein kinase (ERK1/ERK2, or p42/p44MAPKs) the p38 kinases [22, 23]; and the c-JunNH2-terminal kinases/stress-activated protein kinases (JNK/SAPKs)   [24-27].

Though thrombin is most often considered as a haemostatic protein, its roles as mitogen and chemoattractant are well described [29-33].  To date, no evidence has been presented demonstrating a possible direct and long-term effect that thrombin preparations may have on anastomotic patency and vein graft failure.  We had tested the impact of topical bovine thrombin affect at the anastomosis.

Materials and Methods:

Surgical Procedure:  We have developed a porcine arteriovenous (AV) graft model that used to investigate the proliferative response and aid in the development of new therapies to prevent intimal-medial hyperplasia and improve graft patency.  Left carotid artery to right external jugular vein fistulas were made using standard 6mm PTFE (Atrium Medical) in the necks of swine.  Immediately following completion of the vascular anastomosis, flow rate were recorded in the venous outflow tract and again after 7 days.  In one group of animals (n=4), the venous outflow tract was developed a significant proliferative response. For each set of test groups 5,000 units of thrombin JMI versus saline control on the vascular anastomosis at the completion of the surgical procedure used.   Porcine external jugular veins were harvested at 24h and 1 week to characterize the molecular nature of signaling process at the anastomosis.

Ki67 Immunostaining:  The harvested vein grafts were fixed in formalin for 24h at 25C before transferred into 70%ETOH if necessary, then the samples were cut and placed in paraffin blocks.  The veins were dewaxed, blocked the endogenous peroxidase activity in 3% hydrogen peroxide in methanol, and followed by the antigen retrieval in 1M-citrate buffer (pH 6.0).  The samples were cooled, rinsed with PBS before blocking the sections with 5% goat serum.  The sections were immunoblotted for Ki67 clone MSB-1 (DakoCode# M7240) in one to fifty dilution for an hour at room temperature, visualized through biotinylated secondary antibody conjugation (Zymed, Cat # 85-8943) to the tertiary HRP-Streptavidin enzyme conjugate, colored by the enzyme substrate, DAB (dinitro amino benzamidine) as a chromogen, and counterstained with nuclear fast.  As a result, positive tissues became brown and negatives were red.

MAPKs Immunostaining:  The staining of MAPKs differs at the antigen retrieval, completed with Ficin from Zymed and rinsed. The immunoblotting, primary antibody incubation, done at 4 C overnight with total and activated forms of each MAPKs, which are being rabbit polyclonal antibodies used at 1/100 dilution (Cell Signaling) ERK, pERK, JNK, pJNK, p38, and except pp38 which was a mouse monoclonal antibody.  The chromogen exposure accomplished by Vectastain ABC system (Vector Laboratories) and completed with DAB/Ni.

Immunoblotting:  Protein extracts were homogenized in 1g/10ml (w/v) tissue to RIPA (50mM Tris-Cl (pH 8.0), 5 mM EDTA, 150 mM NaCl, 1% Nonidet P-40, 0.5% sodium deoxycholate, 0.1% SDS). Before running the samples on the 4-20% SDS-PAGE, protein concentration were measured by Bradford Assay (BioRad) and adjusted. Following the transfer onto 0.45mM nitrocellulose membrane, blocked in 5% skim milk phosphate buffered saline at 4oC for 4h.  Immunoblotted for activated MAPKs and washed the membranes in 0.1% Tween-20 in PBS.  The pERK (42/44 kDA), pp38 (43kDA), and pJNK (46, 54 kDa) protein visualized with the polyclonal antibody roused against each in rabbit (1:5000 dilution from 200mg/ml, Cell Signaling) and chemiluminescent detection of anti-rabbit IgG conjugated with horseradish peroxidase (ECL, Amersham Corp).

RNA isolation and RT-PCR: The harvested vessels were kept in RNAlater (Ambion, Austin, TX).   The total RNA was isolated by RNeasy mini kit (Qiagen, Cat#74104) fibrous animal tissue protocol, using proteinase K as recommended.

The two-step protocol had been applied to amplify cDNA by Prostar Ultra HF RT PCR kit (Stratagene Cat# 600166).  At first step, cDNA from the total RNA had been synthesized. After denaturing the RNA at 65 oC for 5 min, the Pfu Turbo added at room temperature to the reaction with random primers, then incubated at 42oC for 15min for cDNA amplification.   At the second step, hot start PCR reaction had been designed. The reaction conditions were one cycle at 95oC for 1 min, 40 cycles for denatured at 95oC for 1 min, annealed at 50 oC 1min, amplified at 68 oC for 3min, finally one cycle of extension at 68 oC for 10 min in robotic arm thermocycler.  The gene specific primers were for PAR1 5’CTG ACG CTC TTC ATG CCC TCC GTG 3’(forward), 5’GAC AGG AAC AAA GCC CGC GAC TTC 3’ (reverse); PAR2 5’GGT CTT TCT TCC GGT CGT CTA CAT 3’ (forward), 5’CCA TAG CAG AAG AGC GGA GCG TCT 3’ (reverse); PAR3 5’ GAG TCC CTG CCC ACA CAG TC 3’ (forward), 5’ TCG CCA AAT ACC CAG TTG TT  3’(reverse), PAR4 5’ GAG CCG AAG TCC TCA GAC AA 3’ (forward), 5’ AGG CCA AAC AGA GTC CA 3’ (reverse).

CTGF and Cyr61:  The same method we used for the early expression genes cysteine rich gene (Cyr61) and CTGF by use of the gene specific primers.  For CTGF the primers were  forward and reverse respectively The primers CTGF-(forward) 5′- GGAGCGAGACACCAACC -3′ and CTGF-(reverse) CCAGTCATAATCAAAGAAGCAGC ; Cyr61- (forward)  GGAAGCCTTGCT CATTCTTGA  and Cyr61- (reverse) TCC AAT CGT GGC TGC ATT AGT were used for RT-PCR.  The conditions were hot start at 95C for 1 min, fourty cycles of denaturing for 45 sec at 95C, annealing for 45 sec at 55C and amplifying for 2min at 68C, followed by extension cycle for 10 minutes at 68C.


First we had shown the presence of PAR receptors, PAR1, PAR2, PAR3, and PAR4, on the cell membrane by RT-PCR (Figure 1, Figure 1- PAR expression on veins after 24hr) on the vein tissues treated or not treated with thrombin.   Figure 1 illustrates RT-PCR analysis of harvested control and thrombin treated veins 24hr after AV graft placement using primers for PARs.   We had showed that (Figure 1) there was an increased expression of PAR receptors after the thrombin treatment.    These data demonstrate that all the PAR mRNA can be detected in test veins with the elevation of expression after 24 hr  treatment with BT.  This data  the hypothesis for the function of PAR receptors in vascular tissues that  they serve not only as sensors to protease activity in the local environment towards coagulation but also reactivity to protease reagents may increase due to inflammatory or proliferative stimuli.


TBT cause elevation of DNA synthesis at the anastomosis observed by Ki67 immunostaining:

Next question was to make linear correlation between the expressions of PARs  to elevation of DNA synthesis. We analyzed the cell proliferation mechanism by cell cycle specific antibody, Ki67, and displayed its presence on gross histology sections of vein tissues.   Ki67 proteins with some other proteins form a layer around the chromosomes during mitosis, except for the centromers and telemores where there are no genes.  Further, Ki67 functions to protect the DNA of the genes from abnormal activation by cytoplasmic activators during the period of mitosis when the nuclear membrane has disappeared.  If a cell leaves the cell cycle, all the Ki67 proteins disappear within about 20min.  Therefore, measurement of the Ki67 is a very sensitive method to determine the state of the cell behavior after thrombin stimuli.  The expressions of Ki67 on the tissues were highly discrete in thrombin applied veins compare to in saline controls.    Hence, we concluded that the elevation of DNA synthesis was increased due to TBT activity (Figure 2- Ki67 Proliferation, Fig. 2) and there was a defined cellular proliferation not the enlargement of the cells if TBT used.

Proliferation of the tissue depends on pERK

PARs are GPCRs activate downstream MAPKs, and thrombin was a mitogen.   Changes in mitogen activated protein kinases (MAPK), pERK, p-p38, pJNK through both immunocytochemistry and western Immunoblotting were measured.   As a result, we had processed the treated veins and controls with total and activated MAPKs to detect presumed change in their activities due to thrombin application.

First, ERK was examined in these tissues (in Figure 3, Figure 3-The expression of ERK after thrombin treatment in the tissues).  We found that there was a phosphorylation of ERK (Figure3A) compared to paired staining of total protein expression in the experimental column whereas there was no difference between the total and activated staining of control veins.  The western blots showed that the activation of pERK in the TBT treated samples 76% T higher than the controls.  This data suggest that the proliferation of the vein gained by activation of ERK, which detects proliferation, differentiation and development response to extracellular signals as its role in MAPK pathway.

The next target was JNK that plays a role in the inflammation, stress, and differentiation.    In figure 4, Figure 4-The expression of JNK after thrombin treatment in the tissues, there was an activation of JNK when its pair expression was compared suggesting that there should be an inflammatory response after the thrombin application.  This piece supports the previous studies done in Lawson lab for autoimmune response mechanism due to ectopical thrombin use in the patients.   The application of thrombin elevated the activation of JNK almost two fold compare to without TBT in western blots.  Among the other MAPKs we had tested it has the weakest expression towards thrombin treatment.

Finally, we had tested p38 as shown in Figure 5,Figure5-The expression of p38 after thrombin treatment in the tissues.  The expression of p38 was higher than JNK but much lower than ERK.  Unlike JNK it was not showed pockets of expression around the tissue but it was dispersed. If TBT used on the veins the expression of activated p-p38 was almost twice more than the without ectopic thrombin vein tissues.

In general, all MAPKs showed increased in their phosphorylation level.  The level of activated MAPK expression was increased 200% in the tested animal.  The order of expression from high to low would be  ERK, JNK, and p38.

The genetic expression change

The application of thrombin during surgeries may seem helping to place the graft but later even it may even affect to change the genetic expression towards angiogenesis, as a result occluding the vein for replacement.   Overall data about vascularization and angiogenesis show that the cystein rich family genes take place during normal development of the blood vessels as well as during the attack towards the system for protection.  The application of thrombin to stop bleeding ignite the expression of the connective tissue growth factor (CTGF) and cystein rich protein (Cyr61), which are two of the CCN family genes, as we shown in Figure 6, Figure 6- The Expression of CTGF and Cyr61 after Thrombin Treatment.  Cyr61 was expressed at after 24h and 7 days, but CTGF had started to expressed after 7 days of thrombin application on the extrajugular vein.


The ectopical application of thrombin during surgeries should be revised before it used, since according to our data, the application would trigger the expression of PARs in access  that leads to the cell proliferation and inflammation  through MAPKs  as well as  downstream gene activation, such as CGTF and Cyr61 towards angiogenesis. As a result, there would be a very fast occlusion in the replaced vessels that will require another transplant in very short time.

From cell membrane to the nucleus we had checked the affects of thrombin application on the vein tissues.  We had determined that the thrombin is also mitogenic if it is used during surgeries to stop bleeding.  This activity results in elevating the expression of PARs that tip the balance of the cells due to following cellular events.

It has been established by previous studies that, the thrombin regulates coagulation, platelet aggregation, endothelial cell activation, proliferation of smooth muscle cells, inflammation, wound healing, and other important biological functions.  In concert with the coagulation cascade, PARs provide an elegant mechanism that links mechanical information in the form of tissue injury, change of environmental condition, or vascular leak to the cellular responses as if it is a hormonal element function related to time and dose dependent.   Consequently, the protein with so many roles needs to be used with cautions if it is really necessary.

The first line of evidence was visual since we had observed the thickening of the vessel shortly after TBT used.  The histological was established from the evidence of DNA synthesis at S phase by the elevated expression of the Ki67 proteins. These proteins accumulate in cells during cell cycle but their distribution varies within the nucleus at different stages of the cycle.  In the daughter cells following mitosis, the Ki67 proteins are present in the perinuclear bodies, which then fuse to give the early nucleoli, so that their number decreases during the growth1 (G1) phase up to the G1-S transition, giving 1-3 large-round-nucleoli in synthesis (S) phase.  During the S phase, the nucleoli increase in size up to the S-G2 transition, when the nucleoli assume an irregular outline.

Next, level of evidence was the signaling pathway analysis from membrane to the nucleus.  As a result of the application the PAR receptors were increased to respond thrombin, therefore, the MAPKs protein expression was increased (fig 3,4,5). Even though PAR2 does not directly response to thrombin, it is activated indirectly. The elevated levels of MAPKs, pERK,  pJNK and p-p38 in bovine thrombin treated vessels suggested the change of gene expression. These MAPKKs and MAPKs can create independent signaling modules that may function in parallel.  Each module contains three kinases (MAPKKK, MAP kinase kinase, MAPKK, MAPK kinase, and MAPK).  The Raf (MAPKKK) -> Mek (MAPKK) -> Erk (MAPK) pathway is activated by mitotic stimuli, and regulates cell proliferation.  In our data we had detected the elvation of ERK more than the other MAPKs.   In contrast, the JNK and p-38 pathways are activated by cellular stress including telomere shortening, oncogenic activation, environmental stress, reactive oxygen species, UV light, X-rays, and inflammatory cytokines, and regulate cellular processes such as apoptosis.

Finally, the stimuli received from MAPKs cause differentiation of the downstream gene expression, this results in the activation of development mechanism toward angiogenesis.  The hemostasis of the cells needs to be protected very well to preserve the continuity of actions in the adult life.  

Conclusion: Bovine thrombin is a mitogen, which may significantly increased vascular smooth muscle cell proliferation following surgery and repair.  Therefore, we suggest that bovine thrombin use on vascular tissues seriously reconsidered  thinking that there is a diverse response mechanism developed and possibly triggers many other target resulting in a disease according to the condition of the person who receives the care. In long term, understanding these mechanisms will be our future direction to elucidate the function of thrombin from diverse responses such as in transplantation, development and arterosclorosis. In our immediate step, we will elucidate the specific cell type and its cellular response against JMI compared to purified human, purified bovine and topical human thrombin, since veins are made of two kinds of cell populations, endothelial and smooth muscle cells.









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Figure Legends:

Figure 1: The mRNA level expression of PARs have been shown by sensitive RT-PCR.        PAR1 (lanes 1, 5), PAR2 (lanes 2, 6), PAR3 (lanes 3, 7), and PAR4 (Lanes 4, 8) from veins treated with BT for 7 days or control veins. Figure 1- PAR expression on veins after 24hr

Figure 2: The proliferation of the veins shown by Ki67 immunocytochemistry. Treated panel A, and B, untreated Panel C and D, at 4X and 20X magnification respectively.Figure 2- Ki67 Proliferation

Figure 3 : The activity of ERK. (A) Immunostaining of total and activated ERK, Panel A and C for activated ERK, panel B and D for total ERK experiment vs. control respectively; (B)Western immunoblot of pERK, treated vs. untreated veins, (C) Scaled Graph for western immunoblot (C) treated and un-treated with TBT veins.Figure 3-The expression of ERK after thrombin treatment in the tissues

Figure 4: The activity of JNK. (A) Immunostaining of total and activated JNK, Panel A and C for activated JNK, panel B and D for total JNK experiment vs. control respectively; (B)Western immunoblot of pJNK; (C) Scaled Graph for western immunoblot treated and un-treated with TBT veins.Figure 4-The expression of JNK after thrombin treatment in the tissues

Figure 5: The activity of p38. (A) Immunostaining of total and activated p38.  Panel A and C for pp38, panel B and D for p38 experiment vs. control respectively; (B) Western immunoblot of p38 treated vs. untreated veins; (C) Scaled Graph for western immunoblot treated and un-treated with TBT veins.Figure5-The expression of p38 after thrombin treatment in the tissues

Figure 6: The Expression of CTGF and Cyr61 after Thrombin Treatment. (A)CTGF            (B) Cyr61 expressions of treated and un-treated with TBT veins at 24h and 7 days.Figure 6- The Expression of CTGF and Cyr61 after Thrombin Treatment


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Author: Tilda Barliya PhD

Ocular drug delivery is a very challenging field for pharmaceutical scientists.  The unique structure of the eye restricts the entry of drug molecules at the required site of action. The eye and its drugs are classically divided into : Anterior and Posterior segments (1).

Conventional systems like eye drops, suspensions and ointments cannot be considered optimal in  the treatment of vision threatening ocular diseases yet  more than 90% of the marketed ophthalmic formulations are in the form of eye drops.

In the majority of these topical  formulations which target the anterior chamber (the front of the eye) are washed off from the eye by various mechanisms:

  • lacrimation,
  • tear dilution
  • tear turnover
  • Moreover, human cornea comprising of epithelium, substantia propria and endothelium also restricts the ocular entry of drug molecules

Under normal condition the human eye can hold about 25–30 μl of an ophthalmic solution; however after a single blink the volume is reduced to 7–10 μl through nasolacrimal drainage which cause the drug to be systemically absorbed across the nasal mucosa or the gastrointestinal tract. A significant systemic loss from topically applied drugs also occurs from conjunctival absorption into the local circulation (4)

Thus resulting in low ocular  bioavailability of drugs with less than 5% of the drugs entering the eye.   Recently many drug efflux pumps have been identified and significant  enhancement in ocular drug absorption was achieved following their inhibition or evasion. But prolonged use of such inhibitors may result in undesirable effects.

Targeting the posterior chamber is even more difficult due to the tight junctions  of blood retinal barrier (BRB) restrict the entry of systemically administered drugs into the retina. Drugs are therefore delivered to the posterior chamber via:

  • Intravitreal injections
  • Implants
  • periocular injections

Here’s an illustration of the several ocular drug and their administration path

The success of nanoparticle systems for ocular drug delivery may depend on optimizing lipophilic-hydrophilic properties of the polymer-drug system, optimizing rates of biodegradation, and safety. Polymers used for the preparation of nanoparticles should be mucoadhesive and biocompatible. The choice of polymer plays an important role in the release kinetics of the drug from a nanoparticle system (4).

The choice of polymer plays an important role in the release kinetics of the drug from a nanoparticle system. Ocular bioavailability from a mucoadhesive dosage form will depend on the polymer’s bioadhesion characteristics, which are affected by its swelling properties, hydration time, molecular weight, and degree of crosslinking. The binding of drug depends on the physicochemical properties of the molecule as well as of the nanoparticle polymer, and also on the manufacturing process for these nanoparticle systems (4).

Other areas in which nanotechnology may be used is the use as biosensors, cell delivery and scaffolds etc (2)

Delivery of a drug via nanotechnology based product fulfills mainly three  objectives as follows:

  1. enhances drug permeation
  2. controls the release of drug
  3. targets drug

Tiwari et al (1) nicely covered different ocular delivery systems available. In this section we’ll review only few of the these drug products:

Viscosity improver:

The viscosity enhancers used are hydrophilic polymers such as cellulose, polyalcohol and polyacrylic acid. Sodium carboxy methyl cellulose is one of the most important mucoadhesion polymers having mono adhesive strength. Viscosity vehicles increases the contact time and no marked sustaining effect are seen.


Prodrugs enhance comeal drug permeability through modification of the hydrophilic or lipophilicity of the drug . The method includes modification of chemical structure of the drug molecule, thus making it selective, site specific and a safe ocular drug delivery system. Drugs with increased penetrability through prodrug formulations are epinephrine1, phenylephrine, timolol, and pilocarpine. The main indication of these drugs is to treat glaucoma thought epinephrine1 and phenylephrine are also being used to treat redness of the eye  and/or part of dialing eye-drops.

Colloidal Carriers:
Nanoparticles  provide sustained release-and prolonged therapeutic activity when retained in the cul-de-sac after  topical administration and the entrapped drug must be released from the particles at an appropriate rate. Most commonly used polymers are venous poly (alkyl cyanoacrylates), poly Scaprolactone and polylactic-co-glycolic acid, which undergo hydrolysis in tears. Enhanced permeation across the cornea was also observed when poly (epsilon-caprolactone) nanoparticles were coated with polyethylene glycol.


Liposomes are lipid vesicles containing aqueous core which have been widely exploited in ocular delivery for various drug molecules.Liposomes are favorable for lipophilic drugs and not for-hydrophilic drugs. liposomes has an affinity to bind to, ocular surfaces, and release contents at optimal rates. Coating with bioadhesive polymers to liposomes, prolong the  precomea retention of liposomes. Carbopol 1342-coated pilocarpine containing liposomes were  shown to produce a longer duration of action. Ciprofloxacin (CPFX) was also formulated in  liposomal environmental which lowered tear-driven dilution in the conjunctival sac.  Multilamellar vesicles from lecithin and alpha-L-dipalmithoyl-phosphatidylcholine were used to prepare liposome containing CPFX. This approach produced sustained release of the drug  depending on the nature of the lipid composition selected.

There are many other known forms used in the industry to enhance drug penetration and bioavailability such as dendrimers, bioadhesive polymers, niosomes and microemulsions which will be discussed elsewhere.


Drug delivery by topical and intravitreal routes cannot always be considered safe, effective and patient friendly. Drug delivery by periocular route can potentially overcome many of these limitations and also can provide sustained drug levels in  ocular pathologies affecting both segments. Transporter targeted delivery can be a promising  strategy for many drug molecules. Colloidal carriers can substantially improve the current therapy and may emerge as an alternative following their periocular administration. Ophthalmic drug delivery, more than any other route of administration, may benefit to a full extent from the characteristics of nano-sized drug particles. Other aspect of nanotechnology and ocular drug delivery will be discussed in the next chapter.


1. Tiwari A and Shukla KR. Novel ocular drug delivery systems: An overview. J. Chem. Pharm. Res., 2010, 2(3):348-355

2. Kalishwaralal K., Barathmanikanth S., Pandian SR, Deepak V and Gurunathan S.  Silver nano-a trove for retinal therapies. J Control Release  2010 Jul 14;145(2):76-90

3.Cholkar K., Patel SP., Vadlapudi AD and Mitra AK. Novel Strategies for Anterior Segment Ocular Drug Delivery. J Ocul Pharmaco Ther  2012 Dec 5. [Epub ahead of print]

4. Bucolo C., Drago F and Salomone S. Ocular drug delivery: a clue from nanotechnology. Front Pharmacol. 2012; 3: 188.

5. Vega E., Gamisans F., García M. L., Chauvet A., Lacoulonche F., Egea M. A. (2008). PLGA nanospheres for the ocular delivery of flubiprofen: drug release and interactions. J. Pharm. Sci.97, 5306–5317.

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